Davood Varghai scite author profile

The growing socioeconomic burden of musculoskeletal injuries and limitations of current therapies have motivated tissue engineering approaches to generate functional tissues to aid in defect healing. A readily implantable scaffold‐free system comprised of human bone marrow‐derived mesenchymal stem cells embedded with bioactive microparticles capable of controlled delivery of transforming growth factor‐beta 1 (TGF‐β1) and bone morphogenetic protein‐2 (BMP‐2) was engineered to guide endochondral bone formation. The microparticles were formulated to release TGF‐β1 early to induce cartilage formation and BMP‐2 in a more sustained manner to promote remodeling into bone. Cell constructs containing microparticles, empty or loaded with one or both growth factors, were implanted into rat critical‐sized calvarial defects. Micro‐computed tomography and histological analyses after 4 weeks showed that microparticle‐incorporated constructs with or without growth factor promoted greater bone formation compared to sham controls, with the greatest degree of healing with bony bridging resulting from constructs loaded with BMP‐2 and TGF‐β1. Importantly, bone volume fraction increased significantly from 4 to 8 weeks in defects treated with both growth factors. Immunohistochemistry revealed the presence of types I, II, and X collagen, suggesting defect healing via endochondral ossification in all experimental groups. The presence of vascularized red bone marrow provided strong evidence for the ability of these constructs to stimulate angiogenesis. This system has great translational potential as a readily implantable combination therapy that can initiate and accelerate endochondral ossification in vivo. Importantly, construct implantation does not require prior lengthy in vitro culture for chondrogenic cell priming with growth factors that is necessary for current scaffold‐free combination therapies. Stem Cells Translational Medicine 2017;6:1644–1659

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RNA interfering molecule delivery from in situ forming biodegradable hydrogels for enhancement of bone formation in rat calvarial bone defects

Nguyen

Jeon

Dang

et al. 2018

Acta Biomaterialia

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Delivery of RNAi molecules may be a valuable strategy to guide cell behavior for tissue engineering applications, but to date there have been no reports of a biomaterial system capable of both encapsulation of cells and controlled delivery of incorporated RNA. Here, we present PEG hydrogels that form in situ via Michael type reaction, and that permit encapsulation of hMSCs and the concomitant controlled delivery of siNoggin and/or miRNA-20a. These RNAs were chosen to suppress noggin, a BMP-2 antagonist, and/or PPAR-γ, a negative regulator of BMP-2-mediated osteogenesis, and therefore promote osteogenic differentiation of hMSCs and subsequent bone repair in critical-sized rat calvarial defects. Simultaneous delivery of hMSCs and miRNA-20a enhanced repair of these defects compared to hydrogels containing hMSCs without siRNA or with negative control siRNA. This in situ forming PEG hydrogel system offers an exciting platform for healing critical-sized bone defects by localized, controlled delivery of RNAi molecules to encapsulated hMSCs and surrounding cells.

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Pc 4 photodynamic therapy of U87‐derived human glioma in the nude rat

et al. 2005

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Fluorescence of Pc 4 in U87 cells following photodynamic therapy

Varghai

Azizuddin

Ahmad

et al. 2007

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Monitoring Pc 4-mediated photodynamic therapy of U87 tumors with 18F- fluorodeoxy-glucose PET imaging in the Athymic Nude Rat

Varghai

Cross

Spring-Robinson

et al. 2007

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Introduction:We have previously demonstrated the use of phthalocyanine Pc 4 for the photodynamic therapy (PDT) of ectopic human glial tumors in the athymic nude rat brain. We wish to determine whether 18F-fluorodeoxy-glucose ( 18 F-FDG) Positron Emission Tomography (PET) imaging can detect the reduction in tumor metabolism that must occur after Pc 4-PDT-induced necrosis. Methods: 2.5 x 10 5 U87 cells were injected into the brains of 12 athymic nude rats. After 7 days of tumor growth, all 12 animals were imaged functionally by 18 F-FDG micro-PET (µPET) and structurally by micro-CT and/or micro-MR. These animals received 0.5 mg/kg b.w. Pc 4 via tail-vein injection. One day later the scalp was re-incised and the tumor illuminated with 30 J/cm 2 of 672-nm light from a diode laser. The next day these animals were again 18 F-FDG µPET imaged. Next, the animals were euthanized and their brains were explanted for H&E histology. Results: Histology showed that tumors in the 6 Pc 4-PDT-treated animals demonstrated necrosis ranging from full to frank (severe). Preliminary analysis showed that 18 F-FDG µPET activity in 3 of the 6 non-PDT group (i.e., no tumor necrosis observed) animals was seen to increase 2.28 times following tumor photoirradiation, whereas 18 F-FDG µPET activity in 5 of the 6 PDT group (i.e., tumor necrosis observed) animals was seen to increase 1.15 times following tumor photoirradiation. Discussion: The increased 18 F-FDG µPET activity in the PDT group was unexpected. We had expected this activity to decrease and are presently investigating the cause of this observation.

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Analysis of 18F-fluorodeoxy-glucose PET imaging data captured before and after Pc 4-mediated photodynamic therapy of U87 tumors in the athymic nude rat

Cross

Varghai

Spring-Robinson

et al. 2007

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Introduction: Several workers have proposed the use of PET (Positron Emission Tomography) imaging for the outcome assessment of photodynamic therapy (PDT), especially for deep-seated tumors. We report on our study of 18F-fluorodeoxy-glucose ( 18 F-FDG) PET imaging following brain tumor Pc4-PDT. Our working hypothesis was that the tumor's metabolic activity would decline dramatically following Pc 4-PDT owing to tumor necrosis. Methods: Seven days after intraparenchymal implantation of U87 cells, the brains of 12 athymic nude rats were imaged by micro-CT and/or micro-MR. These animals were also 18 F-FDG micro-PET (µPET) scanned before and after Pc 4-PDT. 18 F-FDG was used to trace metabolic activity that was monitored via µPET. Occurrence of PDT was confirmed on histology. The analysis of 18 F-FDG dose and animal weight normalized µPET activity was studied over the 90 minute µPET scan. Results: Currently, µPET data have been studied for: (1) three of the animals that did not indicate tumor necrosis on histology and were assigned to a "Non-PDT" group, and (2) six animals that exhibited tumor necrosis on histology and were assigned to a "PDT" group. The µPET-detected 18 F-FDG uptake activity in the tumor region before and after photoirradiation increased in the Non-PDT group an average of 2.28 times, and in the PDT group it increased an average of 1.15 times. Discussion: We are investigating the cause of the increase in 18 F-FDG µPET activity that we observed in the PDT group. The methodology used in this study should be useful in determining whether this or other PET, SPECT, or MR functional imaging protocols will detect both the specificity and sensitivity of brain tumor necrosis following Pc 4-PDT.

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Mechanical Analysis of Resorbable Plates for Long-Term Soft-Tissue Molding

Varghai

Chim

Gosain

2011

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Augmentation of Intraorbital Volume with Fat Injection

Brown

Lee

Zwiebel

et al. 2014

Plastic and Reconstructive Surgery

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Davood Varghai

Endochondral Ossification in Critical-Sized Bone Defects via Readily Implantable Scaffold-Free Stem Cell Constructs

RNA interfering molecule delivery from in situ forming biodegradable hydrogels for enhancement of bone formation in rat calvarial bone defects

Pc 4 photodynamic therapy of U87‐derived human glioma in the nude rat

Fluorescence of Pc 4 in U87 cells following photodynamic therapy

Monitoring Pc 4-mediated photodynamic therapy of U87 tumors with 18F- fluorodeoxy-glucose PET imaging in the Athymic Nude Rat

Analysis of 18F-fluorodeoxy-glucose PET imaging data captured before and after Pc 4-mediated photodynamic therapy of U87 tumors in the athymic nude rat

Mechanical Analysis of Resorbable Plates for Long-Term Soft-Tissue Molding

Augmentation of Intraorbital Volume with Fat Injection

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